A device for achieving dynamic charging and balance of battery cells is disclosed. The device is configured for monitoring a plurality of battery voltages from a plurality of battery cells in a multi-cell battery pack. In case of a battery voltage difference between two of the battery cells being greater than a pre-determined voltage difference, the device generates a plurality of balance charging currents for charging the battery cells. In which, each of the balance charging currents is calculated based on remaining charge time, measured battery voltage, and rated battery capacity. Thus, in a charge cycle, one balance charging current for charging the battery cell with low battery voltage is designed to be greater than another one balance charging current for charging the battery cell with high battery voltage. Consequently, elimination of the battery voltage difference existing between any two of the battery cells is achieved.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A device for achieving dynamic charging and balance of battery cells, being applied in a multi-cell battery pack that comprises a plurality of battery cells and a battery management circuit, wherein each of the plurality of battery cells has a rated battery capacity, and the device is integrated in the battery management circuit; the device comprising: a battery voltage sensing unit, being coupled to the plurality of battery cells, so as to apply a battery voltage detection to each of the plurality of battery cells, thereby outputting a plurality of voltage sensing signals; and a battery balancing module, being coupled to the battery voltage sensing unit to receive the plurality of voltage sensing signals, and being also coupled to a controller unit of the battery management circuit; wherein the battery balancing module comprises: a first signal processing unit for converting the plurality of voltage sensing signals to a plurality of battery voltages; a balance executing unit, being coupled to the first signal processing unit for receiving the plurality of battery voltages, and being configured to generate a plurality of balance charging currents for charging the plurality of battery cells of the multi-cell battery pack; and a time counter, being coupled to the balance executing unit, and being employed for conducting a time counting of the multi-cell battery pack while the multi-cell battery pack is charged by the plurality of balance charging currents, thereby outputting a time counting signal to the balance executing unit; wherein the balance executing unit is configured to: calculate, based on the time counting signal and a pre-determined charge limit time of the multi-cell battery pack, a remaining charge time of the multi-cell battery pack; calculate, based on the remaining charge time, a target battery voltage, the plurality of battery voltages, and the rated battery capacity, the plurality of balance charging currents; abate, in case of said balance charging current being greater than a pre-determined maximum charging current, said balance charging current to be equal to the pre-determined maximum charging current; and enhance, in case of said balance charging current being lower than a pre-determined minimum charging current, said balance charging current to be equal to the pre-determined minimum charging current.
2. The device of claim 1, further comprising: a charging current sensing unit, being coupled to the controller unit of the battery management circuit, so as to apply a current detection to a charging current that is transmitted from the controller unit to the multi-cell battery pack, thereby generating a charging current sensing signal.
3. The device of claim 2, wherein the battery balancing module further comprises: a second signal processing unit, being coupled to the charging current sensing unit for receiving the charging current sensing signal, so as to convert the charging current sensing signal to a charging current; wherein the second signal processing unit is also coupled to the balance executing unit, such that the balance executing unit acquires an intensity of the charging current from the second signal processing unit.
4. The device of claim 3, wherein the battery balancing module further comprises: a storage unit, being coupled to the balance executing unit, and storing with a plurality of setting parameters, wherein the plurality of setting parameters comprises: the pre-determined charge time, the target battery voltage and the rated battery capacity.
5. The device of claim 4, wherein the balance executing unit utilizes the following mathematical formula to complete a calculation of the balance charging current:, I B = B C * V target - V cell K * T C ; ( I ) wherein K is a scale coefficient, IB being the balance charging current, Bc being the rated battery capacity, Vtarget being the target battery voltage, Vcell being the battery voltage, and Tc being the remaining charge timer.
6. The device of claim 4, wherein the balance executing unit utilizes the following mathematical formula to complete a calculation of the balance charging current:, I B = B C 2 * V target - V cell K * T C ; ( II ) wherein K being a scale coefficient, IB being the balance charging current, Bc being the rated battery capacity, Vtarget being the target battery voltage, Vcell being the battery voltage, and Tc being the remaining charge time.
7. The device of claim 1, wherein the battery management circuit is configured to further perform a plurality of functions of temperature sensing, overcharge protection, over-discharge protection, overcurrent protection, short circuit protection, and charge time protection.
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March 11, 2022
June 3, 2025
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